ARTICLE pubs.acs.org/jced
Equilibrium Study for the System Tri-n-butyl Phosphate, Normal Paraffin Hydrocarbon, and Nitric Acid Shaila Lalkuwar Bajoria,† Virendra Kisan Rathod,*,† N. K. Pandey,‡ U. Kamachi Mudali,‡ and R. Natarajan‡ † ‡
Department of Chemical Engineering, Institute of Chemical Technology, N.P. Marg, Matunga, Mumbai 400019, India RR&DD, Reprocessing Group, Indira Gandhi Centre for Atomic Research, Kalpakkam, Tamilnadu 603102, India ABSTRACT: Tri-n-butyl phosphate (TBP) in diluent is generally used as a solvent for the extraction of fissile materials in the reprocessing of spent fuels by the PUREX process. The mutual solubility of TBP and water leads to the transfer of some finite amount of TBP into the aqueous phase. The distribution study of TBP between normal paraffin hydrocarbon (NPH) and nitric acid has been studied. Equilibrium curves have been generated for TBP in different concentrations of nitric acid and NPH. The distribution coefficient (Kd) is also calculated by measuring the concentration of associated TBP in the aqueous and organic phase. The effect of an inert diluent on the solubility of TBP in nitric acid is also studied. It has been found that the distribution coefficient value varies with the concentration of TBP, nitric acid, and NPH. Nitric acid partitioning between TBP and water has also been studied. The concentration of nitric acid in both phases was determined by the titration method. It has also been proven that the concentration of nitric acid varies during this equilibrium study due to 1:1 complex formation with TBP by hydrogen bonding. The equilibrium study of this TBP-NPH-nitric acid system will aid in finding out the amount of TBP in different concentrations of nitric acid in the presence of a diluent. This study will be useful in nuclear waste management generated by spent fuels of reprocessing origin.
’ INTRODUCTION Equilibrium studies play a very important role in liquidliquid extraction studies. It is an important factor which decides the distribution of solute between two liquid phases. A system is said to be in equilibrium when no mass transfer takes place between the two phases and all of the physical properties of each phase become uniform. Tri-n-butyl phosphate (TBP) is the most frequently used solvent in liquidliquid extraction for nuclear fuel reprocessing. It is used as a solvent in nuclear chemistry for the recovery of the actinide elements, like Th, U, Np, and Pu. As the density and viscosity of TBP is very much similar to that of water, the separation of TBP from water becomes difficult. This problem can be solved by diluting TBP with a light, saturated hydrocarbon, such as n-dodecane, normal paraffin hydrocarbon (NPH), kerosene, and so forth, which reduces the density of TBP and aids in phase separation.1 In the TBP-NPH-HNO3 system, TBP distributes itself between the organic and the aqueous phases. This distribution in the two phase system can be explained as follows: TBP dissolves in NPH by dimerization1 and can be represented by eq 1, an equilibrium reaction in the organic phase xTBPorg T ðTBPÞx org
ð1Þ
but dissolves in nitric acid due to stable equimolar, that is, 1:1 complex formation by hydrogen bonding.2 It can be represented by eq 2, an equilibrium reaction in the aqueous phase TBPaq þ HNO3aq T TBP 3 HNO3aq
ð2Þ
and the equilibrium distribution coefficient (Kd) for TBP associated between the two phases can be represented by eq 3. Kd ¼
TBPorg TBPaq
r 2011 American Chemical Society
ð3Þ
A similar type of distribution also takes place for nitric acid. Collopy and Canvedish2 reported this equilibrium reaction. This extraction of nitric acid from aqueous solutions by TBP in NPH can be explained by eq 4. 3 Hþ aq þ NOaq þ TBPorg T HNO3 3 TBPorg
ð4Þ
while its distribution in the aqueous phase is as shown in eq 5. 3 HNO3aq þ H2 Oaq T H3 Oþ aq þ NOaq
ð5Þ
The above equations explain that when TBP in NPH is contacted with nitric acid two types of mass transfer take place. TBP distributes itself between NPH and nitric acid, but simultaneously nitric acid is also distributed between TBP and water. A number of extraction studies of nitrates with TBP have been done in the past. Alcock et al.3 have measured the mutual solubility of TBP and water in the presence of nitric acid and also in the presence of various diluents like kerosene, heptane, hexane, cyclohexane, toluene, and benzene. The partition of nitric acid between water and TBP in kerosene at various TBP concentrations has also been determined. Collopy and Cavendish2 have published the results on equilibrium constants for the system TBP-water-nitric acid. Burns and Hanson4 have studied the distribution of nitric acid between TBP and water. Hardy et al.5 have also obtained data on the partitioning of nitric acid and water between aqueous nitric acid and pure TBP solutions and have also analyzed these data in the terms of the GibbsDuhem equation. Sagert and Lee6 have measured the distribution of lower trialkyl phosphates like trimethyl, triethyl, Received: December 29, 2010 Accepted: April 25, 2011 Published: May 05, 2011 2856
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Journal of Chemical & Engineering Data
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Table 1. Characteristics of Substances Used in This Study with Their Chemical Abstracts Service (CAS) Registry Numbers purity substance
CAS reg. no.
molecular formula
tri-n-butyl phosphate
126-73-8
(C4H9O)3 PO
normal paraffin hydrocarbon
64771-72-8
CnH2nþ2n [n = 10 to 16]
nitric acid
7697-37-2
HNO3
tripropyl, and tributyl phosphate between water and dodecane as a function of temperature and trialkyl phosphate concentration. Ayedi et al.7 have presented the phase equilibrium diagram for the ternary system H2OH3PO4TBP at (298.15 and 323.15) K. The bimodal curves, tie lines, and distribution curves along with the plait point by Hand's method have also been determined. The distribution coefficient of nitrous acid has been measured as a function of the nitrous and nitric acid concentrations in the aqueous phase and functions of TBP and uranium concentrations in the organic phase by Uchiyama et al.8 The solubility of TBP in plutonium nitrate solution and in highly radioactive liquid waste (HRLW) of the PUREX process has been determined by Kuno et al.,9 and the variation in solubility of TBP with the concentration of nitric acid and temperature has also been studied. Lawson and Hughes10 have designed a kinetic model for extraction of nitric acid by TBP and have found that the extraction is controlled by a combination of diffusion and chemical kinetic processes. Baldwin and Higgins11 have extracted TBP using various diluents and determined the distribution coefficient of TBP in solvents having lower miscibility. All of the above authors have mainly focused on the distribution of nitric acid between TBP and water at different temperatures and in the presence of various inert diluents, but data on distribution of TBP between nitric acid and the diluent are still not available, and the equilibrium diagram for the TBP-diluent-nitric acid system has not yet been published. In the PUREX process, the spent fuels are typically dissolved in nitric acid, and 30 % TBP in a paraffinic diluent is used as an extracting solvent. As TBP has some solubility in nitric acid, this leads to its transfer into the aqueous phase. Removal of this dissolved TBP is of direct interest in reprocessing processes for safe disposal of this nuclear waste. Diluents like n-dodecane, NPH, kerosene, and so forth, affect the solubility of TBP in the aqueous phase. It is therefore of fundamental importance to study the equilibrium diagram of the ternary system TBP-diluent-nitric acid. The equilibrium study of this TBP-diluent-nitric acid system will aid in measuring the amount of TBP in different concentrations of nitric acid in the presence of diluent. The equilibrium data generated will also be useful in calculating the number of theoretical plates required for designing a column to remove dissolved TBP from aqueous waste. The main objectives of this paper are as follows: (i) to find the equilibrium concentration of TBP at various concentration of nitric acid ranging from (0.3 to 3) M by using different amounts of diluent in TBP as the organic phase; (ii) to calculate the distribution coefficient for TBP and determination of the factors affecting its value; (iii) to measure the solubility of TBP in nitric acid as a function of diluent; and (iv) to study the variation in the concentration of nitric acid at equilibrium. The diluent used in the present study is NPH.
’ EXPERIMENTAL SECTION Materials. TBP and nitric acid were supplied by SD Fine Chemicals. NPH, also known as liquid paraffin light, was supplied
% 97
specific gravity kg 3 dm3 0.978 0.749
70
1.41
Figure 1. Schematic of the reaction assembly for equilibrium study.
by Prabhat Chemicals. All reagents used were of analytical reagent grade. The characteristics of the reagents used in this study are shown in Table 1. Equilibration and Phase Separation. The partition study was performed by equilibrating the organic and aqueous phases in a 1:1 ratio. A baffle reactor of 100 cm3 capacity with a glass stirrer was used as the mixing vessel. An electrically driven motor was used for stirring the solution, and the speed was adjusted using a speed regulator as shown in Figure 1. A total of 50 cm3 of TBP in NPH was contacted with 50 cm3 of nitric acid at 500 rpm for around 3 h at 30 °C ( 2 °C in the reactor. The phases were allowed to separate overnight at room temperature to ensure complete separation before analysis. The settling technique was preferred over centrifugation since the latter technique might invariably result in an increase in the temperature of the solution and hence disturb the solution equilibrium. The same procedure was repeated for different percentages of TBP in NPH ranging from 0.1 % to 100 % (v/v). The concentration of nitric acid in the aqueous phase was also varied from (0.3 to 3) M during the equilibrium study. All of the experiments were carried out in triplicate, and the average values have been reported. The deviation in the results obtained is e ( 3 %. These deviations have been represented graphically using error bars which signify uncertainties in the measurements. TBP Concentration Determinations. The TBP concentration in the organic phase was determined by gas chromatography (GC) and in the aqueous phase by high performance liquid 2857
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Figure 2. Graphical representation of the equilibrium data for TBP diluentnitric acid system. Symbols: b, 0.3 M HNO3; 9, 1 M HNO3; 2, 3 M HNO3.
chromatography (HPLC). The analysis of each sample was done thrice to check the reproducibility of the results. The Kd values obtained were precise within ( 2 %. Analysis of TBP on GC. A ThermoFisher model GC-8 gas chromatograph with a flame ionization detector (FID) was used. A 10 % OV-17 SS column with 80/100 mesh and 1/800 2 m in length was used for separation. The operating conditions were as follows: column temperature, 235 °C, injector port and detector temperatures, 300 °C, and nitrogen was used as the carrier gas. Two microliters (2 μL) of the organic sample were injected into the column using a borosilicate glass syringe. A calibration curve was plotted for quantifying the amount of TBP in NPH after equilibrium. Analysis of TBP on HPLC. A Jasco made HPLC system equipped with a R.I detector model RI-2031, an isocratic pump model PU-2080, a Rheodyne manual sample injector model 77251, and LC NET II AD box with Borwin DV software was used. A HPLC column oven model HCO-02 was used to maintain the temperature constant throughout the analysis. The HiQ sil C18 HS 4.6 mm 250 mm in size was used as an analytical column. The mobile phase was a mixture of acetronitrile and water. Nitric Acid Partitions. The concentration of nitric acid in both the phases after equilibration was determined by a titration method. The NaOH solution was used as a base and phenolphthalein as an indicator during the titration. The color change at the end point was from colorless to pale pink. The concentration of NaOH solution used for titration was ranged from (0.3 to 3) M depending on the concentration of nitric acid in the aqueous phase. Each sample was titrated thrice with NaOH. The uncertainty reported in the results was e 0.1 %.
’ RESULTS AND DISCUSSION The distribution coefficient was generated by varying the concentration of TBP, nitric acid, and NPH in the solution. The effect of concentration of TBP, nitric acid, and NPH on the equilibrium data for the TBP-NPH-nitric acid system has been determined and is discussed below. Effect of TBP Concentration. The effect of TBP concentration on the equilibrium data of the TBP-NPH-HNO3 system has
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Figure 3. Effect of nitric acid and NPH on Kd values of TBP. Symbols: b, 0.3 M HNO3; 9, 1 M HNO3; 2, 3 M HNO3.
Table 2. Effect of TBP Concentration on Distribution Coefficient of Nitric Acid Kd for nitric acid conc. Of TBP in org. phase/%
0.3 M
1M
3M
0.1
0
0
0
0.2
0
0
0
0.5 1
0 0
0 0
0 0
3
0
0
0
5
0
0
0
10
0
0
0.06
20
0
0.05
0.13
30
0.02
0.07
0.2
40
0.02
0.16
0.28
50 60
0.04 0.04
0.23 0.3
0.33 0.37
70
0.08
0.39
0.47
80
0.13
0.53
0.54
90
0.19
0.59
0.67
100
0.25
0.65
0.75
been investigated. The partition of TBP between nitric acid and NPH is shown in Figure 2. The equilibrium curve was generated by varying the concentration of TBP in the organic phase ranging from 0.1 % to 100 % (v/v). It has been observed that the distribution coefficient values of TBP increase sharply with the concentration of TBP in the organic phase as shown in Figure 3. It was found that, as the concentration of TBP in the organic phase increases, more TBP is transferred into the aqueous phase, and hence, the solubility of TBP in the aqueous phase increases. The distribution coefficient values of TBP increase with increasing the aqueous phase TBP concentration because of dimerization of TBP. The results obtained are in agreement with that reported by Schulz et al.1 They measured the distribution coefficient of TBP as a function of TBP concentration in the aqueous phase. Germain and Pluot12 have also obtained equilibrium data for the TBP2 M nitric aciddiluent system. They found that the distribution coefficient value of TBP increases 2858
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Figure 4. Effect of NPH on the solubility of TBP in the aqueous phase. Symbols: b, 0.3 M HNO3; 9, 1 M HNO3; 2, 3 M HNO3.
sharply with the concentration of TBP in the aqueous phase. Sagert and Lee6 reported that the distribution coefficient increases with the concentration of TBP due to aggregation of TBP in dodecane. Hence, it is confirmed from the equilibrium study that the distribution coefficient for this system depends upon the concentration of TBP in both the phases and is a function of TBP concentration in the organic phase. Effect of Nitric Acid Concentration. The effect of nitric acid concentration on the equilibrium data of the TBPNPH HNO3 system has also been studied. The equilibrium study was performed with different concentrations of nitric acid ranging from (0.3 to 3) M. The distribution coefficient values increase with the concentration of acid as shown in Figure 3. It has been assumed that this is due to a decrease in the solubility of TBP in nitric acid with the concentration of nitric acid in the aqueous phase. At lower nitric acid concentrations, more TBP is transferred into the aqueous phase, but as the concentration of nitric acid increases, this transfer process of TBP into the aqueous phase slows down. This is because of extraction of nitric acid into the organic phase by TBP which limits the solubility of TBP in the aqueous phase. Hence, it has been noticed that the distribution coefficient values increase with nitric acid concentration in the aqueous phase. The distribution coefficient value was found to be a maximum for 3 M HNO3 and a minimum for 0.3 M HNO3. The results obtained are in concordance with that reported by Germain and Pluot.12 They have reported that the solubility of TBP in the nitric acid is due to complex formation by hydrogen bonding, and the distribution coefficient value rises with HNO3 concentration due to the lower solubility of TBP in the concentrated range of nitric acid. Effect of NPH Concentration. The influence of NPH on the equilibrium data for the TBPNPHHNO3 system has also been investigated. It was found that the distribution coefficient value decreases with the concentration of NPH in the organic phase in the presence of different concentrations of nitric acid as shown in Figure 3. The effect of NPH on the solubility of TBP in nitric acid is demonstrated in Figure 4. The result obtained reveals that the presence of both NPH and nitric acid affects the distribution of TBP between the phases. The distribution of TBP in the organic phase is due to dimerization,1 and that of nitric acid is because of hydrogen bonding.2 The solubility of TBP in the aqueous phase is high at low concentrations of NPH but
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Figure 5. Variation in the concentration of nitric acid at equilibrium. Symbols: b, 0.3 M HNO3; 9, 1 M HNO3; 2, 3 M HNO3.
decreases with the concentration of NPH in the organic phase. NPH is a nonpolar diluent which limits the solubility of TBP in the nitric acid. The distribution of TBP in the aqueous phase is more in 0.3 M HNO3 than 1 and 3 M HNO3, as the solubility of TBP decreases with the concentration of nitric acid. It has also been observed from Figure 4 that the distribution curves obtained for TBP are of the different shapes in three different concentrations of nitric acid, that is, 0.3 M, 1 M, and 3 M. This difference in the curve shape is due to the extraction of nitric acid to different extents by TBP in the organic phase. The distribution coefficient values for nitric acid decrease in the order as follows: 3 M HNO3, 1 M HNO3, and 0.3 M HNO3 as shown in Table 2. It is assumed that at equilibrium TBP and nitric acid both distribute themselves between the organic and the aqueous phases. It was found that, as TBP is transferred to different extents in the aqueous phase at different nitric acid concentrations, the shapes of the distribution curves are different. Hence, the mass transfer of both TBP and nitric acid governs the shapes of the distribution curves in 0.3 M, 1 M, and 3 M HNO3. Many authors like Schulz et al.,1 Germain and Pluot,12 and Sagert and Lee6 have reported similar results. They have found that the distribution of TBP in the organic phase is because of dimerization of TBP rather than the association between TBP and the diluent NPH. The distribution coefficient value increases with decreases in NPH concentration due to a lower dimerization constant. Nitric Acid Partitioning. The change in the concentration of nitric acid at equilibrium when contacted with different percentages of TBP in NPH is shown in Figure 5. The distribution coefficient for nitric acid has been determined by measuring the amount of nitric acid in the aqueous and organic phases, and the results obtained are summarized in Table 2. It was observed that the concentration of nitric acid in the aqueous phase decreases with the concentration of TBP in the aqueous phase. The concentration of 0.3 M, 1 M, and 3 M HNO3 reduces to 0.24 M, 0.603 M, and 1.716 M HNO3, respectively, at equilibrium after pure TBP contact. This is due to the extraction of nitric acid by TBP into the organic phase. Acids are soluble in TBP and form strong bonds with the PdO group of TBP. It has been reported by Collopy and Cavendish2 that TBP forms an equimolar complex with nitric acid due to hydrogen bonding which has resulted from 2859
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Journal of Chemical & Engineering Data the transfer of nitric acid into the organic phase. Hoh and Wang13 have also studied the distribution of nitric acid between water and TBP and observed the same reason for this partition. Alcock et al.3 agree with this complex formation mechanism and determined the solubility of nitric acid in TBP. It has also been found that the distribution coefficient value for nitric acid increases with the concentration of nitric acid due to more complex formation. Burns and Hanson4 observed the same trend for the distribution coefficient at higher nitric acid concentration in the aqueous phase. Hence, the results obtained are in good agreement with those observed by various other investigators.
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(13) Hoh, Y. C.; Wang, W. K. Rate studies on nitric acid-Tributyl phosphate extraction and stripping. Ind. Eng. Chem. Process Des. Dev. 1980, 19, 64–67.
’ NOTE ADDED AFTER ASAP PUBLICATION This paper was published ASAP on May 5, 2011. Two minor text changes were made in the Results and Discussion section. The revised paper was reposted on May 16, 2011.
’ CONCLUSIONS The equilibrium data have been successfully generated for the TBPNPHnitric acid system for three different concentrations of nitric acid. The distribution coefficient values have been found to be dependent on the concentration of TBP, nitric acid, and NPH in the system. It has also been proven that the concentration of nitric acid varies during this equilibrium study due to complex formation with TBP. The results obtained will be of prime importance in the reprocessing of spent fuels from the PUREX process and will be helpful in nuclear waste management. ’ AUTHOR INFORMATION Corresponding Author
*E-mail:
[email protected]. Tel. no.: 91-22-33612020. Fax no. 91-22-33611020.
’ REFERENCES (1) Schulz, W. W.; Burger, L. L.; Navratil, J. D. Science and Technology of Tributyl phosphate; CRC Press: Boca Raton, FL, 1990. (2) Collopy, J. J.; Cavendish, J. H. Equilibrium constants for the system tri-n-butyl phosphate-water-nitric acid. J. Phys. Chem. 1960, 64, 1328–1330. (3) Alcock, K.; Grimley, S. S.; Helay, T. V.; Kennedy, J.; Mckay, H. A. C. The extraction of nitrates by tri-n-butyl phosphate (TBP) Part 1- The system TBP þ Diluent þ H2O þ HNO3. Trans. Faraday Soc. 1956, 52, 39–47. (4) Burns, P. E.; Hanson, C. Distribution of nitric acid between tri-nbutyl phosphate and water. J. Appl. Chem. 1964, 14, 117–121. (5) Hardy, C. J.; Davis, W.; Mrochek The system: tri-n-butyl phosphate (TBP)-nitric acid-water-I. Activities of TBP in equilibrium with aqueous nitric acid and partial molar volumes of the three components in the TBP phase. J. Inorg. Nucl. Chem. 1966, 28, 2001–2014. (6) Sagert, N. H.; Lee, W. The distribution of trialkylphosphates between dodecane and water. Can. J. Chem. 1980, 58, 1463–1467. (7) Ayedi, H. F.; Sahnoun, R. D.; Feki, M. J. Liquid-liquid equilibria of the ternary system water þ phosphoric acid þ tributyl phosphate at 298.15 and 323.15 K. J. Chem. Eng. Data 2002, 47, 861–866. (8) Uchiyama, G.; Hotoku, S.; Fujine, S. Distribution of nitrous acid between tri-n-butyl phosphate/n-dodecane and nitric acid. Solvent Extr. Ion Exch. 1998, 16, 1171–1190. (9) Kuno, Y.; Hina, T.; Masui, T. Solubility of tributyl phosphate in plutonium nitrate solution and highly radioactive liquid waste solution. J. Nucl. Sci. Technol. 1993, 30, 567–572. (10) Lawson, P. N. E.; Hughes, M. A. A kinetic model for extraction of nitric acid by tri-n-butyl phosphate. Chem. Eng. J. 1989, 40, 111–119. (11) Baldwin, W. H.; Higgins, C. E. Liquid-liquid distribution. Tributyl phosphate between immiscible solvents. J. Chem. Eng. Data 1974, 19, 152–154. (12) Germain, M.; Pluot, P. Diluent washing of aqueous phase using centrifugal contractors; ISEC 80, Liege, Belgique, 1980. 2860
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